/*** * * Copyright (c) 1996-2002, Valve LLC. All rights reserved. * * This product contains software technology licensed from Id * Software, Inc. ("Id Technology"). Id Technology (c) 1996 Id Software, Inc. * All Rights Reserved. * * This source code contains proprietary and confidential information of * Valve LLC and its suppliers. Access to this code is restricted to * persons who have executed a written SDK license with Valve. Any access, * use or distribution of this code by or to any unlicensed person is illegal. * ****/ #include "extdll.h" #include "utils.h" #include "cbase.h" #include "monsters.h" #include "schedule.h" #include "flyingmonster.h" #define FLYING_AE_FLAP (8) #define FLYING_AE_FLAPSOUND (9) extern DLL_GLOBAL edict_t *g_pBodyQueueHead; int CFlyingMonster :: CheckLocalMove ( const Vector &vecStart, const Vector &vecEnd, CBaseEntity *pTarget, float *pflDist ) { // UNDONE: need to check more than the endpoint if (FBitSet( pev->flags, FL_SWIM) && (UTIL_PointContents(vecEnd) != CONTENTS_WATER)) { // ALERT(at_aiconsole, "can't swim out of water\n"); return FALSE; } TraceResult tr; UTIL_TraceHull( vecStart + Vector( 0, 0, 32 ), vecEnd + Vector( 0, 0, 32 ), dont_ignore_monsters, large_hull, edict(), &tr ); // ALERT( at_console, "%.0f %.0f %.0f : ", vecStart.x, vecStart.y, vecStart.z ); // ALERT( at_console, "%.0f %.0f %.0f\n", vecEnd.x, vecEnd.y, vecEnd.z ); if (pflDist) { *pflDist = ( (tr.vecEndPos - Vector( 0, 0, 32 )) - vecStart ).Length();// get the distance. } // ALERT( at_console, "check %d %d %f\n", tr.fStartSolid, tr.fAllSolid, tr.flFraction ); if (tr.fStartSolid || tr.flFraction < 1.0) { if ( pTarget && pTarget->edict() == gpGlobals->trace_ent ) return LOCALMOVE_VALID; return LOCALMOVE_INVALID; } return LOCALMOVE_VALID; } BOOL CFlyingMonster :: FTriangulate ( const Vector &vecStart , const Vector &vecEnd, float flDist, CBaseEntity *pTargetEnt, Vector *pApex ) { return CBaseMonster::FTriangulate( vecStart, vecEnd, flDist, pTargetEnt, pApex ); } Activity CFlyingMonster :: GetStoppedActivity( void ) { if ( pev->movetype != MOVETYPE_FLY ) // UNDONE: Ground idle here, IDLE may be something else return ACT_IDLE; return ACT_HOVER; } void CFlyingMonster :: Stop( void ) { Activity stopped = GetStoppedActivity(); if ( m_IdealActivity != stopped ) { m_flightSpeed = 0; m_IdealActivity = stopped; } pev->angles.z = 0; pev->angles.x = 0; m_vecTravel = g_vecZero; } float CFlyingMonster :: ChangeYaw( int speed ) { if ( pev->movetype == MOVETYPE_FLY ) { float diff = FlYawDiff(); float target = 0; if ( m_IdealActivity != GetStoppedActivity() ) { if ( diff < -20 ) target = 90; else if ( diff > 20 ) target = -90; } pev->angles.z = UTIL_Approach( target, pev->angles.z, 220.0 * gpGlobals->frametime ); } return CBaseMonster::ChangeYaw( speed ); } void CFlyingMonster :: Killed( entvars_t *pevAttacker, int iGib ) { pev->movetype = MOVETYPE_STEP; ClearBits( pev->flags, FL_ONGROUND ); pev->angles.z = 0; pev->angles.x = 0; CBaseMonster::Killed( pevAttacker, iGib ); } void CFlyingMonster :: HandleAnimEvent( MonsterEvent_t *pEvent ) { switch( pEvent->event ) { case FLYING_AE_FLAP: m_flightSpeed = 400; break; case FLYING_AE_FLAPSOUND: if ( m_pFlapSound ) EMIT_SOUND( edict(), CHAN_BODY, m_pFlapSound, 1, ATTN_NORM ); break; default: CBaseMonster::HandleAnimEvent( pEvent ); break; } } void CFlyingMonster :: Move( float flInterval ) { if ( pev->movetype == MOVETYPE_FLY ) m_flGroundSpeed = m_flightSpeed; CBaseMonster::Move( flInterval ); } BOOL CFlyingMonster:: ShouldAdvanceRoute( float flWaypointDist ) { // Get true 3D distance to the goal so we actually reach the correct height if ( m_Route[ m_iRouteIndex ].iType & bits_MF_IS_GOAL ) flWaypointDist = ( m_Route[ m_iRouteIndex ].vecLocation - pev->origin ).Length(); if ( flWaypointDist <= 64 + (m_flGroundSpeed * gpGlobals->frametime) ) return TRUE; return FALSE; } void CFlyingMonster::MoveExecute( CBaseEntity *pTargetEnt, const Vector &vecDir, float flInterval ) { if ( pev->movetype == MOVETYPE_FLY ) { if ( gpGlobals->time - m_stopTime > 1.0 ) { if ( m_IdealActivity != m_movementActivity ) { m_IdealActivity = m_movementActivity; m_flGroundSpeed = m_flightSpeed = 200; } } Vector vecMove = pev->origin + (( vecDir + (m_vecTravel * m_momentum) ).Normalize() * (m_flGroundSpeed * flInterval)); if ( m_IdealActivity != m_movementActivity ) { m_flightSpeed = UTIL_Approach( 100, m_flightSpeed, 75 * gpGlobals->frametime ); if ( m_flightSpeed < 100 ) m_stopTime = gpGlobals->time; } else m_flightSpeed = UTIL_Approach( 20, m_flightSpeed, 300 * gpGlobals->frametime ); if ( CheckLocalMove ( pev->origin, vecMove, pTargetEnt, NULL ) ) { m_vecTravel = (vecMove - pev->origin); m_vecTravel = m_vecTravel.Normalize(); UTIL_MoveToOrigin(ENT(pev), vecMove, (m_flGroundSpeed * flInterval), MOVE_STRAFE); } else { m_IdealActivity = GetStoppedActivity(); m_stopTime = gpGlobals->time; m_vecTravel = g_vecZero; } } else CBaseMonster::MoveExecute( pTargetEnt, vecDir, flInterval ); } float CFlyingMonster::CeilingZ( const Vector &position ) { TraceResult tr; Vector minUp = position; Vector maxUp = position; maxUp.z += 4096.0; UTIL_TraceLine(position, maxUp, ignore_monsters, NULL, &tr); if (tr.flFraction != 1.0) maxUp.z = tr.vecEndPos.z; if( pev->flags & FL_SWIM ) { return UTIL_WaterLevel( position, minUp.z, maxUp.z ); } return maxUp.z; } BOOL CFlyingMonster::ProbeZ( const Vector &position, const Vector &probe, float *pFraction) { int conPosition = UTIL_PointContents( position ); if ( ((pev->flags & FL_SWIM) == FL_SWIM) ^ (conPosition == CONTENTS_WATER)) { // SWIMING & !WATER // or FLYING & WATER // *pFraction = 0.0; return TRUE; // We hit a water boundary because we are where we don't belong. } int conProbe = UTIL_PointContents(probe); if( conProbe == conPosition ) { // The probe is either entirely inside the water (for fish) or entirely // outside the water (for birds). // *pFraction = 1.0; return FALSE; } Vector ProbeUnit = (probe-position).Normalize(); float ProbeLength = (probe-position).Length(); float maxProbeLength = ProbeLength; float minProbeLength = 0; float diff = maxProbeLength - minProbeLength; while (diff > 1.0) { float midProbeLength = minProbeLength + diff/2.0; Vector midProbeVec = midProbeLength * ProbeUnit; if( UTIL_PointContents( position + midProbeVec ) == conPosition ) { minProbeLength = midProbeLength; } else { maxProbeLength = midProbeLength; } diff = maxProbeLength - minProbeLength; } *pFraction = minProbeLength/ProbeLength; return TRUE; } float CFlyingMonster::FloorZ( const Vector &position ) { TraceResult tr; Vector down = position; down.z -= 2048; UTIL_TraceLine( position, down, ignore_monsters, NULL, &tr ); if ( tr.flFraction != 1.0 ) return tr.vecEndPos.z; return down.z; }